Phosphorous trifluoride co-gas for carbon implants

ABSTRACT

Processes and systems for carbon ion implantation include utilizing phosphorous trifluoride (PF 3 ) as a co-gas with carbon oxide gas, and in some embodiments, in combination with the lanthanated tungsten alloy ion source components advantageously results in minimal oxidation of the cathode and cathode shield. Moreover, acceptable levels of carbon deposits on the arc chamber internal components have been observed as well as marked reductions in the halogen cycle, i.e., WF x  formation.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a NON-PROVISIONAL of U.S. Application Ser. No. 62/426,249, filed Nov. 24, 2016, the contents of which are incorporated by reference in its entirety.

BACKGROUND

The present invention relates generally to ion implantation systems, and more specifically to carbon implantation utilizing a carbon oxide gas and a phosphorous trifluoride co-gas.

In the manufacture of semiconductor devices, ion implantation is used to dope semiconductors with impurities. Ion implantation systems are often utilized to dope a workpiece, such as a semiconductor wafer, with ions from an ion beam, in order to either produce n- or p-type material doping, or to form passivation layers during fabrication of an integrated circuit. Such beam treatment is often used to selectively implant the wafers with impurities of a specified dopant material, at a predetermined energy level, and in controlled concentration, to produce a semiconductor material during fabrication of an integrated circuit. When used for doping semiconductor wafers, the ion implantation system injects a selected ion species into the workpiece to produce the desired extrinsic material.

A typical ion implanter includes an ion source, an ion extraction device, a mass analysis device, a beam transport device and a wafer processing device. The ion source generates ions of desired atomic or molecular dopant species. These ions are extracted from the source by an extraction system, typically a set of electrodes, which energize and direct the flow of ions from the source, forming an ion beam. Desired ions are separated from the ion beam in a mass analysis device, typically a magnetic dipole performing mass dispersion or separation of the extracted ion beam. The beam transport device, typically a vacuum system containing a series of focusing devices, transports the ion beam to the wafer processing device while maintaining desired properties of the ion beam. Finally, semiconductor wafers are transferred in to and out of the wafer processing device via a wafer handling system, which may include one or more robotic arms, for placing a wafer to be treated in front of the ion beam and removing treated wafers from the ion implanter.

Ion sources (commonly referred to as arc ion sources) generate ion beams used in implanters and can include heated filament cathodes for creating ions that are shaped into an appropriate ion beam for wafer treatment. U.S. Pat. No. 5,497,006 to Sferlazzo et al., for example, discloses an ion source having a cathode supported by a base and positioned with respect to a gas confinement chamber for ejecting ionizing electrons into the gas confinement chamber. The cathode of the Sferlazzo et al. is a tubular conductive body having an endcap that partially extends into the gas confinement chamber. A filament is supported within the tubular body and emits electrons that heat the endcap through electron bombardment, thereby thermionically emitting ionizing electrons into the gas confinement chamber.

Carbon has emerged as a widely used dopant in the semiconductor industry for a wide variety of material modification applications. For example, carbon implantation is often used to inhibit diffusion of co-dopants or for enhancing stability of the doped region. In this regard, carbon dioxide and/or carbon monoxide are two commonly used dopant gas sources for carbon implantation. The residual oxygen from the disassociation of the carbon molecule can oxidize the chamber liners as well as damage the cathode shield causing a premature failure of the ion source. Moreover, residual carbon deposits and flaking due to the cracking of carbon dioxide and/or carbon monoxide are also known to shorten ion source lifetimes.

BRIEF SUMMARY

Disclosed herein are processes and systems for implanting carbon into a substrate. In one or more embodiments, the process for implanting carbon into a substrate includes ionizing a carbon oxide gas source and a co-gas comprising phosphorous trifluoride in an ion source chamber to produce carbon ions and phosphorous oxide; and implanting the carbon ions into the substrate.

In one or more embodiments, a process for implanting carbon ions into a workpiece includes supplying a mixture of a carbon oxide gas and a phosphorous trifluoride gas to an ion source; ionizing the carbon oxide gas and the phosphorous trifluoride gas with the ion source at a stoichiometry effective to create a feedstream of ionized carbon and a byproduct comprising phosphorous oxides; extracting the ionized carbon within the plasma to form an ion beam; and exposing the workpiece to the ion beam to implant the ionized carbon into the workpiece.

The disclosure may be understood more readily by reference to the following detailed description of the various features of the disclosure and the examples included therein.

BRIEF DESCRIPTION OF THE DRAWINGS

Referring now to the figures wherein the like elements are numbered alike:

FIG. 1 is a block diagram of an exemplary ion implantation system in accordance with several aspects of the present disclosure;

FIG. 2 illustrates a perspective view of an exemplary ion source for use in the present disclosure;

FIG. 3 illustrates a perspective view of an exemplary arc chamber for use in the present disclosure;

FIG. 4 illustrates a conventional tungsten cathode and shield after 20 hours of operation;

FIG. 5 illustrates a lanthanated tungsten cathode and shield after 20 hours of operation;

FIG. 6 illustrates a conventional arc chamber after running 30 hours with no co-gas.

FIG. 7 illustrates a lanthanated tungsten arc chamber after running 30 hours with various source materials with no co-gas.

FIG. 8 graphically illustrates emission characteristics of pure tungsten and lanthanated tungsten; and

FIG. 9 is a chart illustrating various characteristics of various compounds.

DETAILED DESCRIPTION

The present disclosure is generally directed toward carbon implantation utilizing a phosphorous trifluoride as co-gas with a carbon oxide gas. In one or more embodiments, carbon implantation with phosphorous trifluoride as the co-gas is in combination with an ion implantation system including at least one conductive component therein formed of lanthanated tungsten. Suitable carbon oxides include, without limitation, carbon monoxide, carbon dioxide, carbon suboxide, and the like, and mixtures thereof. In one or more embodiments, the ion source and beam line components utilized in the ion implantation system for carbon implantation includes surfaces or components formed of a lanthanated tungsten alloy for improved lifetime, stability, and operation of the ion implantation system. For carbon implantation, utilizing phosphorous trifluoride (PF₃) as the co-gas with the carbon oxide, and in some embodiments, in combination with the lanthanated tungsten alloy ion source components advantageously results in minimal oxidation of the cathode and cathode shield, thereby extending the operating lifetimes. Moreover, acceptable levels of carbon deposits on the arc chamber internal components including, among others the arc slit have been observed as well as marked reductions in tungsten oxide formation (i.e., WO_(x), wherein x is from 1 to 6). As for the carbon ions that are generated, these ions can be selectively extracted and accelerated at high velocities suitable for ion implantation into a workpiece of interest. Carbon implants are generally in the 1-30 keV energy range and the doses vary from low to mid E13s to mid E15s depending on the application.

Accordingly, the present disclosure will now be described with reference to the drawings, wherein like reference numerals may be used to refer to like elements throughout. It is to be understood that the description of these aspects are merely illustrative and that they should not be interpreted in a limiting sense. In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It will be evident to one skilled in the art, however, that the present disclosure may be practiced without these specific details. Further, the scope of the disclosure is not intended to be limited by the embodiments or examples described hereinafter with reference to the accompanying drawings, but are intended to be only limited by the appended claims and equivalents thereof.

It is also noted that the drawings are provided to give an illustration of some aspects of embodiments of the present disclosure and therefore are to be regarded as schematic only. In particular, the elements shown in the drawings are not necessarily to scale with each other, and the placement of various elements in the drawings is chosen to provide a clear understanding of the respective embodiment and is not to be construed as necessarily being a representation of the actual relative locations of the various components in implementations according to an embodiment of the disclosure. Furthermore, the features of the various embodiments and examples described herein may be combined with each other unless specifically noted otherwise.

It is also to be understood that in the following description, any direct connection or coupling between functional blocks, devices, components, circuit elements or other physical or functional units shown in the drawings or described herein could also be implemented by an indirect connection or coupling. Furthermore, it is to be appreciated that functional blocks or units shown in the drawings may be implemented as separate features or circuits in one embodiment, and may also or alternatively be fully or partially implemented in a common feature or circuit in another embodiment. For example, several functional blocks may be implemented as software running on a common processor, such as a signal processor. It is further to be understood that any connection which is described as being wire-based in the following specification may also be implemented as a wireless communication, unless noted to the contrary.

In accordance with one aspect of the present disclosure, FIG. 1 illustrates an exemplary ion implantation system 100. The ion implantation system 100 in the present example generally includes a terminal 102, a beamline assembly 104, and an end station 106.

Generally speaking, an ion source 108 in the terminal 102 is coupled to a power supply 110 to ionize a dopant gas 112 (i.e., source gas) into a plurality of ions from the ion source to form an ion beam 114. The ion beam 114 is directed through an entrance 116 of a mass analyzer 117 and out an aperture 118 towards the end station 106. In the end station 106, the ion beam 114 bombards a workpiece 120, which is selectively clamped or mounted to a chuck 122, e.g., an electrostatic chuck. Once embedded into the lattice of the workpiece 120, the implanted ions change the physical and chemical properties of the workpiece. Because of this, ion implantation is used in semiconductor device fabrication and in metal finishing, as well as various applications in materials science research.

The ion beam 112 of the present disclosure can take any form, such as a pencil or spot beam, a ribbon beam, a scanned beam, or any other form in which ions are directed toward end station 106, and all such forms are contemplated as falling within the scope of the disclosure.

According to one exemplary aspect, the end station 106 includes a process chamber 124, such as a vacuum chamber 126, wherein a process environment 128 is associated with the process chamber. The process environment 128 generally exists within the process chamber 124, and in one example, includes a vacuum produced by a vacuum source 130 (e.g., a vacuum pump) coupled to the process chamber 124 and configured to substantially evacuate the process chamber 126. Further, a controller 132 is provided for overall control of the ion implantation system 100.

The ion source 108 (also called an ion source chamber), for example, can be constructed using refractory metals (W, Mo, Ta, etc.) and graphite in order to provide suitable high temperature performance, whereby such materials are generally accepted by semiconductor chip manufacturers. The source gas 112 is used within the ion source 108, wherein source gas may or may not be conductive in nature. However once the source gas 112 is cracked or fragmented, the ionized gas by-product can be very corrosive. In the present disclosure, the source gas is a mixture including carbon oxide and at least phosphorous trioxide as a co-gas.

The demand from device manufacturers for longer source life, increased ion beam currents, ion beam stability and non-dedicated species operation has pushed conventional ion source designs to their limits. Each of these demands are not mutually exclusive, however, whereby one or more performance characteristics are typically sacrificed to provide an ion source that does not fail prematurely.

The highly corrosive nature of fluorides and oxides generated from cracking carbon oxides such as carbon monoxide (CO) and/or carbon dioxide (CO₂) and/or carbon suboxides (C₃O₂), for example, challenges the conventional refractory metals used to construct the different ion implantation components such as the ion source 108 and components associated therewith. The formation of tungsten dioxide (WO₂) and tungsten trioxide (WO₃), for example, on the internal source components can negatively impact ion implantation transitions to other species, such as ¹¹B and ⁴⁹BF₂, until the residual oxygen released from the tungsten oxides is below some threshold level.

In one or more embodiments, the present disclosure utilizes lanthanated tungsten alloys or lanthanated tungsten alloys with other refractory metals alloyed at a predetermined percentage of a rare earth metal for components (e.g., internal arc chamber components) associated with the ion source 108. In many cases, providing such lanthanated tungsten alloy components can prevent damage from residual oxygen. In many cases, providing such lanthanated tungsten alloy components can prevent damage from residual fluorine and/or oxygen. The reaction of O⁻ with lanthanum, for example, results in a protective surface layer that is very stable at temperatures greater than 2000° C., whereas tungsten oxides are very volatile (e.g., halogen cycle) and lead to shorter lifetimes of the ion source, as well as increased ion beam instabilities. Further, the ion source of the present disclosure when formed of a lanthanated tungsten alloy provides improved cathode electron emission due to its lower work function and decreased formation of tungsten carbide or oxides on the cathode tip, thus reducing cathode electron emission for carbon implants.

In addition to using lanthanated tungsten alloys or lanthanated tungsten alloys with other refractory metals alloyed at a predetermined percentage of a rare earth metal to construct the arc internal components, the arc chamber body and other components of the ion implantation system that are downstream of the arc chamber can also be constructed utilizing such a material. For example, extraction electrode optics (e.g., suppression and ground apertures) and any other downstream ion beam defining apertures, liners, and ion beam strike plates can be formed of such a lanthanated tungsten material. Any components that are susceptible to etching or sputtering by extracted oxygen ions are considered as being candidates for being formed of such a material, where volatile corrosive conductive gases formed in conventional systems would typically coat critical insulators.

For example, in an ion source 200 illustrated in FIG. 2, the tungsten hexafluoride or other resultant material may decompose on surfaces 202 of various internal components 203 of the ion source, such as on surfaces of a cathode 204, a repeller 206 and arc slit optics (not shown) associated an arc chamber 208 of the ion source. This is called a halogen cycle as shown in equation, but the resultant material can also precipitate and/or condense back onto walls 210 or liners 212 or other components of the arc chamber 208, as well as the arc slit in the form of a contaminant material 214 (e.g., solid-state particulate contaminants) The liners 212, for example, comprise replaceable members 215 operably coupled to a body 216 of the arc chamber 208, wherein the liners are comprised of graphite or various other materials. The replaceable members 215, for example, provide wear surfaces that can be easily replaced after a period of operation of the arc chamber 208.

Another source of contaminant material 214 deposited onto the internal components 203 arises from the cathode 204 when the cathode is indirectly heated (e.g., a cathode composed of tungsten or tantalum), whereby the indirectly heated cathode is used to start and sustain the ion source plasma (e.g., a thermionic electron emission). The indirectly heated cathode 204 and the repeller 206 (e.g., an anticathode), for example, are at a negative potential in relation to the body 216 of the arc chamber 208, and both the cathode and repeller can be sputtered by the ionized gases. The repeller 206, for example, can be constructed from tungsten, molybdenum, or graphite. Yet another source of contaminant material 214 deposited on the internal components 203 of the arc chamber 208 is the dopant material (not shown), itself. Over time, these deposited films of contaminant material 214 can become stressed and subsequently delaminate, thereby shortening the life of the ion source 200.

The present disclosure advantageously can include the use of lanthanated tungsten alloy in ion implant systems to mitigate etching and contamination issues during carbon implantation. In one or more embodiments, phosphorous trifluoride is utilized as a co-gas with the carbon source gases such as carbon monoxide and/or carbon dioxide in combination with the lanthanum tungsten alloy ion source components as described herein. In one or more other embodiments, the conductive components of the ion implantation system are formed of tungsten, or the like. The use of phosphorous trifluoride as a co-gas for carbon implants and the components formed or coated with lanthanated tungsten alloy provides numerous advantages.

For example, the main failure mode when using carbon monoxide and/or carbon dioxide as a dopant gas for carbon implantation is the oxidation and subsequent reduction in mass of the cathode and cathode shield. When running for extended times it is not uncommon for the cathode shield to oxidize at a very high rate leading to premature source failure. The introduction of phosphorous trifluoride as a co-gas with the carbon monoxide and/or carbon dioxide gases results in stable cathode power performance and carbon beam currents over extended periods of time. While not wanting to be bound by theory, it is believed that the presence of phosphorous results in the formation of phosphorous oxides such as P₄O₆ and P₄O₁₀, which have relatively low melting points of 23.8° C. and 422° C., respectively. These compounds can be pumped from the chamber while in vapor form, thereby significantly minimizing oxidation of the cathode and cathode shield. Consequently, a balance can be achieved between cathode shield oxidation rate and carbon deposits based on the amount of available oxygen. Moreover, the optional use of lanthanated tungsten components will further reduce the cathode shield oxidation rate due to formation of a stable lanthanum oxide compound, e.g., La₂O₃.

The ratio of the carbon oxide to the phosphorous trifluoride can be readily optimized by detecting the formation of the phosphorous oxides based on analysis of the atomic mass unit (amu) spectra. The ratio is optimized once the phosphorous oxides are no longer detectable and the relative beam current is maintained at a desirable amount. The phosphorous trifluoride co-gas can be inserted as a separate gas from a different string or can be premixed in the same bottle beforehand, once a desired ratio has been determined. The operating pressures in the ion source are in the low to mid E⁻⁵ Torr range. High current ion source life varies with species usage but can be several hundred hours.

Carbon deposits can form in and along the ion extraction optics, also referred to as the arc slit opening, reducing the extracted ion current and subsequently the desired dopant beam current. These deposits form as a direct result of generating the desired carbon dopant or form interaction of the ionization byproducts and the refractory metals from which the arc chamber is constructed. These carbon deposits are prone to delamination from the internal arc chamber surface, which can cause the cathode and repeller assemblies to electrically short. Once this occurs, the arc chamber needs to be cleaned to remove the carbon deposits. The use of phosphorous trifluoride reduces the formation of carbon deposits by forming CF_(x) and CO gases, which can be easily pumped from the chamber, thereby minimizing and/or eliminating any damage that these deposits may have formed.

When using a hydrogen based co-gas with a carbon based dopant there will be energetic cross contamination due to the formation of B¹¹H¹ (AMU 12) and C¹². It has also been observed that there is no cross contamination of B¹¹ and C¹² when using phosphorous trifluoride as a co-gas with carbon monoxide and/or carbon dioxide. For, example, ⁴⁹BF₂ implants have a separation of one atomic mass unit (amu) as shown in the reaction schemes (I) and (II) below, which can be readily resolved using known techniques.

CO₂+PF₃

C(12)+O(16)+F(19)+CO(28)+P(31)+CF(31)+PF(50)   I.

CO+PF₃

C(12)+O(16)+F(19)+CO(28)+P(31)+CF(31)+PF(50)   II.

Additionally, carbon implantation utilizing a phosphorous trifluoride as co-gas with a carbon monoxide or carbon dioxide gas in combination lanthanum tungsten components increases component longevity, among other benefits. The cracking of phosphorous trifluoride yields phosphorous and fluorine, wherein as noted above phosphorous can advantageously reduce the amount of available oxygen, which is known to damage the cathode shield whereas the fluorine will react with available tungsten to create a halogen cycle (i.e., WF_(x), wherein x is from 1 to 6). The resulting tungsten fluoride decomposes depositing tungsten on hot surfaces such as the cathode, cathode shield, and repeller, which decreases the source lifetime. The presence of the PF₃ co-gas in combination with use of lanthanum tungsten to construct the internal arc chamber components as described herein minimizes and controls the halogen cycle as evidenced in reaction scheme (III) below.

19CO+7PF₃+LaW

17C⁺+O+20F+2CO+P+PO+2La₂O₃+3W+WO₃+P₄O₆.   III.

Protective films of LaF₃ or La₂O₃ are produced, which are thermally stable up to about 1490° C. and about 2300° C., respectively. As the WLaO₃ resides in the tungsten grain boundary, it will continually diffuse to the surface and replenish the protective coating. This in turn reduces the formation of volatile refractory gases. When lanthanum is sputtered, etched or evaporated into the arc chamber that contains tungsten, oxygen, and/or fluorine, the lanthanum does not form highly reactive and unstable components such as MoF_(x), WF_(x), and TaF_(x). Instead, the presence of the lanthanum results in the formation of stable oxides or fluoride compounds that are also deposited onto the interior arc chamber surfaces, which further protects the interior surfaces.

FIG. 3 illustrates an exemplary ion source 300 (also called an arc chamber or ion source chamber) in which the present disclosure may be utilized. The arc chamber 300 of FIG. 3 is similar in many ways to the arc chamber 208 of FIG. 2. As illustrated in FIG. 3, the arc chamber 300 has a body 302 defining and interior region 304 of the arc chamber. The arc chamber 300, for example, comprises one or more electrodes 304. The one or more electrodes 305, for example, comprise a cathode 306, and a repeller 308. The arc chamber 300, for example, further comprises an arc slit 310 for extraction of ions from the arc chamber. One or more liners 312 are operably coupled to the body 302 of the arc chamber 300. The body 302, for example, may further comprise one or more walls 314 operably coupled to, or integrated with, the body. In one example, a cathode shield 316 generally surrounds a periphery of the cathode 306.

In accordance with the present disclosure, one or more of the electrodes 305 (e.g., one or more of the cathode 306 and repeller 308), the cathode shield 316 comprise or are comprised of lanthanated tungsten. Further, one or more of the liners 312, walls 314, and/or extraction aperture 310 of the arc chamber 300 can comprise or are comprised of lanthanated tungsten. The present disclosure presently appreciates that lanthanated tungsten is more resistant to chemical attack as compared to pure tungsten used in convention ion sources. The presently considered theory is that lanthanated tungsten forms a lanthanum oxide layer on the exposed surface during the ionization process taking place in the arc chamber 300. Since this lanthanum oxide layer is chemically more stable than conventional chemistries, it generally inhibits further corrosion.

FIG. 4 illustrates a conventional cathode 400 and its corresponding cathode shield 402 (e.g., a tubular member that covers the cathode) after running CO₂ for 20 hours, wherein the cathode and cathode shield are formed of tungsten. As illustrated in FIG. 4, severe oxidation 404 of the cathode shield 402 and its subsequent deposition through thermal decomposition onto the cathode sidewall 406 are present. As shown in FIG. 4, the shield 402 has been oxidized such that the shield has been deleteriously separated into two pieces 408A and 408B.

FIG. 5 illustrates cathode 500 and corresponding cathode shield 502 after running CO₂ for 20 hours, wherein the cathode and cathode shield are comprised of lanthanum tungsten. As illustrated in FIG. 5, the reduction in the oxidation of the cathode shield and reduced tungsten deposition onto the cathode sidewall 504 is readily apparent when compared to the conventional cathode and shield of FIG. 4.

FIG. 6 illustrates a conventional cathode in a conventional arc chamber 410 after running 30 hours of GeF₄ with no co-gas. Excessive deposition of tungsten 412 onto the cathode 400 and the repeller 414 and the etching of the arc chamber liners 416, 418 are clearly present.

FIG. 7 illustrates an arc chamber 508 having one or more components (e.g., one or more of the cathode 500, cathode shield 502, repeller 510, chamber walls 512, extraction aperture (not shown), lines 514, and the like formed of lanthanum tungsten after running GeF₄, SiF₄ and BF₃ with no co-gas for 10 hours each. As illustrated in FIG. 7, all of the exposed surfaces 516 in arc chamber are formed of lanthanated tungsten, but such an example is not to be considered limiting. As shown in FIG. 6 there is no significant deposition of tungsten onto the cathode and the repeller (e.g., no halogen cycle is present), where there are minimal signs of etching of the arc chamber liner(s) 514.

FIG. 8 is graph 600 illustrating emission characteristics of pure tungsten and lanthanated tungsten, where the maximum stable emission of 4 A/cm² is at 1900 K (e.g., reference to thoriated tungsten of 3 A/cm² at 2100 K). Pure tungsten, for example, thermionic emission is one hundred times less at ˜2300 K.

FIG. 9 is a table 700 illustrating characteristics for various materials after reacting with fluorine and oxygen. Lanthanum oxide, for example, has a melting point approximately 1000° C. higher than standard tungsten dioxide, which means that it is much more stable. The arc chamber liners described above typically operate at approximately 700-800° C., the cathode operates at approximately 2500° C., and the cathode shield operates at approximately 2000° C. Accordingly, lanthanated tungsten components provide a stable compound, which doesn't break down easily at high temperatures after reacting with fluorine.

The present disclosure provides lanthanated tungsten as an alloy or mixed with other refractory metals (e.g., molybdenum, tantalum, etc.) for construction of the arc chamber (e.g., ion source chamber) and/or other electrode components. The present disclosure provides a lanthanated alloy having a predetermined amount of lanthanum (e.g., 1-3% lanthanum powder by weight of the component). For example, the predetermined amount of lanthanum mixed with the desired metal (e.g., tungsten) and isostatically pressed to form the component. The lanthanated tungsten, for example, may define the whole component, or the component may be coated or otherwise deposited over the component. When lanthanated tungsten components of the present disclosure are exposed to process gases, the resulting compounds are generally stable at operation temperatures of the ion source. For example, La₂F₃ is formed in the presence of fluorine, and is stable up to greater than 1400° C. Thus, surfaces associated with the ion source can be considered to be passivated. Likewise, when lanthanated tungsten is exposed to oxygen in process conditions, an oxide compound is formed, which is also quite stable. Thus, the lanthanated tungsten “ties up” the fluorine or oxygen and generally prevents the fluorine or oxygen from etching tungsten off the components. In one example, any component that is exposed to the plasma in the arc chamber comprises or is comprised of lanthanated tungsten.

A halogen cycle associated with fluorine (e.g., WF_(x), wherein x is 1 to 6), for example, when exposed to a hot surface, provides a gas that is volatile and subsequently decomposes, leaving residual tungsten behind, whereby the fluorine goes back into the plasma to scavenge more tungsten. By providing the components exposed to the plasma as being comprised of lanthanated tungsten, the halogen cycle is basically eliminated or broken. As such, minimal or no WF_(x) is formed, and less material is present to decompose on the hot surfaces to make them increase in mass.

Conventionally, halogen cycles have been problematic when fluorine-based dopant gases are utilized. Germanium, for example, is a worst case, followed by BF₃ and SiF₄, whereby the liners and other components of the ion source are conventionally etched, pitted, etc. When used with oxygen, the cathode may be oxidized. When used with tungsten, WO₂ is formed, among other tungsten oxides.

Deposits of carbon on the cathode can further create tungsten carbide. Because the cathode is indirectly heated, it will emit electrons at approximately 2500° C. When this happens, the source does not emit electrons, whereby plasma arc current drops, plasma density drops, and ion beam current drops. By providing the cathode as being comprised of lanthanated tungsten, for example, there is also no need to run the co-gas with carbon. The ion source may be operated with no co-gas because the emissivity of the cathode is reduced (e.g., 100 times better than standard tungsten) due to the lanthanum. As such, the ion source generally protects itself, its work function is lower, and it can emit electrons more easily at a lower power.

When running carbon containing gases, carbon monoxide or carbon dioxide with oxygens (or carbon containing gas with oxygen), a significant amount of tungsten dioxide and tungsten trioxide can be formed in the arc chamber. When a subsequent transition to boron (B₁₁, BF₃) is desired, the ion source is unstable until the oxygen disposed therein is removed. Thus, until the oxygen is removed, the previous tuning solution associated with the ion source will not work well. Thus, in accordance with the present disclosure, since there is no tungsten oxide formed, the lanthanated tungsten provides for a passivating of the chamber, thus protecting it.

In accordance with one example, extraction electrodes utilized in extract the ions from the ion source (e.g., optics plates) can be made of lanthanated tungsten. When fluorine is utilized in a conventional tungsten extraction electrode, for example, the fluorine will sputter the apertures and combine to form tungsten fluoride (WF_(x)) gas, which is corrosive. Further, insulators are often provided between the extraction plates, whereby the fluorinated tungsten will attack the insulators (Al₂O₃), which further creates a deleterious conductive coating on the insulator. Thus, in accordance with the present disclosure, the aperture plates are formed of lanthanated tungsten, thus mitigating such deleterious conduction.

The present disclosure contemplates components upstream of the AMU magnet to be comprised of lanthanated tungsten, such as the ion source, extraction electrode optics, and exit of source chamber. Arc chamber internal components may be comprised of lanthanated tungsten, such as any liners, arc slit, cathode, repeller, and cathode shield associated with the ion source chamber. Further, the AMU entrance aperture can also be formed of lanthanated tungsten. Additionally, components further downstream of AMU (e.g., anywhere along the beamline) may be comprised of lanthanated tungsten in a similar manner

Although the invention has been shown and described with respect to a certain embodiment or embodiments, it should be noted that the above-described embodiments serve only as examples for implementations of some embodiments of the present invention, and the application of the present invention is not restricted to these embodiments. In particular regard to the various functions performed by the above described components (assemblies, devices, circuits, etc.), the terms (including a reference to a “means”) used to describe such components are intended to correspond, unless otherwise indicated, to any component which performs the specified function of the described component (i.e., that is functionally equivalent), even though not structurally equivalent to the disclosed structure which performs the function in the herein illustrated exemplary embodiments of the invention. In addition, while a particular feature of the invention may have been disclosed with respect to only one of several embodiments, such feature may be combined with one or more other features of the other embodiments as may be desired and advantageous for any given or particular application. Accordingly, the present invention is not to be limited to the above-described embodiments, but is intended to be limited only by the appended claims and equivalents thereof.

This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to make and use the invention. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims. 

What is claimed is:
 1. A process for implanting carbon into a substrate, the process comprising: ionizing a carbon oxide gas source and a co-gas comprising phosphorous trifluoride in an ion source chamber to produce carbon ions and phosphorous oxide; and implanting the carbon ions into the substrate.
 2. The process of claim 1, wherein the carbon oxide source comprises carbon suboxide, carbon monoxide, carbon dioxide, a carbon containing gas and an oxygen gas mixture or combinations thereof.
 3. The process of claim 1, wherein the ion source chamber comprises one or more components formed of or coated with lanthanum tungsten.
 4. The process of claim 1, wherein the one or more components are selected from the group consisting of a cathode, cathode shield, a repeller, a liner, an arc slit, a source chamber wall, a liner, aperture plates, extraction electrodes, and an arc chamber body.
 5. The process of claim 1, wherein the phosphorous trifluoride relative to the carbon oxide gas is at a ratio such that formation of the phosphorous oxides is at about zero.
 6. The process of claim 1, wherein the carbon oxide gas is carbon monoxide and reacts with the phosphorous trifluoride in accordance with reaction scheme I having corresponding atomic mass units shown in parenthesis: CO+PF₃

C(12)+O(16)+F(19)+CO(28)+P(31)+CF(31)+PF(50).   I.
 7. The process of claim 1, wherein the carbon oxide gas is carbon dioxide and reacts with the phosphorous trifluoride in accordance with reaction scheme II having corresponding atomic mass units shown in parenthesis: CO₂+PF₃

C(12)+O(16)+F(19)+CO(28)+P(31)+CF(31)+PF(50).   II.
 8. The process of claim 3, wherein the carbon oxide gas is carbon monoxide and reacts with the phosphorous trifluoride in accordance with reaction scheme III having corresponding atomic mass units shown in parenthesis: 19CO+7PF₃+LaW

17C⁺+O+20F+2CO+P+PO+2La₂O₃+3W+WO₃+P₄O₆.   III.
 9. The process of claim 1, wherein the lanthanated tungsten comprises lanthanum in an amount from 1 to 3% by weight.
 10. A process for implanting carbon ions into a workpiece, the process comprising: supplying a mixture of a carbon oxide gas and a phosphorous trifluoride gas to an ion source; ionizing the carbon oxide gas and the phosphorous trifluoride gas with the ion source at a stoichiometry effective to create a feedstream of ionized carbon and a byproduct comprising phosphorous oxides; extracting the ionized carbon within the plasma to form an ion beam; and exposing the workpiece to the ion beam to implant the ionized carbon into the workpiece.
 11. The process of claim 10, wherein the carbon oxide gas is selected from the group of gases consisting of carbon monoxide, carbon dioxide, carbon suboxide, a carbon-containing gas and an oxygen gas mixture, and combinations thereof.
 12. The process of claim 10, wherein the phosphorous trifluoride gas relative to the carbon oxide gas is at a ratio such that formation of the phosphorous oxides is at about zero.
 13. The process of claim 10, further comprising evacuating the phosphorous oxides from the ion source chamber.
 14. The process of claim 10, wherein the carbon oxide gas is carbon monoxide and reacts with the phosphorous trifluoride in accordance with reaction scheme I having corresponding atomic mass units shown in parenthesis: CO+PF₃

C(12)+O(16)+F(19)+CO(28)+P(31)+CF(31)+PF(50).   I.
 15. The process of claim 10, wherein the carbon oxide gas is carbon dioxide and reacts with the phosphorous trifluoride in accordance with reaction scheme II having corresponding atomic mass units shown in parenthesis: CO₂+PF₃

C(12)+O(16)+F(19)+CO(28)+P(31)+CF(31)+PF(50).   II.
 16. The process of claim 10, wherein the ion source and an ion implantation system containing the ion source comprises one or more components formed of or coated with lanthanum tungsten.
 17. The process of claim 16, wherein the carbon oxide gas is carbon monoxide and reacts with the phosphorous trifluoride in accordance with reaction scheme III having corresponding atomic mass units shown in parenthesis: 19CO+7PF₃+LaW

17C⁺+O+20F+2CO+P+PO+2La₂O₃+3W+WO₃+P₄O₆.   III.
 18. The process of claim 16, wherein the lanthanated tungsten comprises lanthanum in an amount from 1 to 3% by weight component or the coating, respectively. 